Remembering Mumps
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Published in the journal:
. PLoS Pathog 11(5): e32767. doi:10.1371/journal.ppat.1004791
Category:
Pearls
doi:
https://doi.org/10.1371/journal.ppat.1004791
Summary
article has not abstract
What Is Mumps?
The mumps virus belongs to the family of paramyxoviruses. It has a single-strand, nonsegmented, negative-sense RNA genome and is spread by the respiratory route. Following a 12–25-day incubation period, infection frequently causes the classic symptom of mumps: painfully swollen parotid salivary glands (parotitis). Some complications of infection include hearing loss, orchitis, oophoritis, mastitis, and pancreatitis. Mumps may also result in aseptic meningitis and, infrequently, encephalitis (5%–10% and <0.5% of unvaccinated cases, respectively) [6]. Importantly it has been estimated that as many as 30% of infections in unvaccinated individuals may be asymptomatic [7].
What Do We Know about the Immune Response to Mumps?
The reasons why symptomatic mumps infections occur among vaccinated individuals are not clear because there are no definitive correlates of protective immunity for mumps. It is assumed that neutralizing antibody is essential for protection, but repeated attempts to define a protective threshold titer have been inconclusive [8]. Some evidence suggests that memory T lymphocytes are probably necessary to confer protection, but they are likely not sufficient [9]. By several measures, the immune response to mumps virus (both wild type and vaccine) seems inherently weak. The average mumps in vitro plaque reduction neutralization titer is low (typically ≤1:256) even after wild-type infection. In addition, the predominant antibody response appears to be directed to the nucleoprotein, which is a non-neutralizing target [10]. Finally, some reports indicate that the frequency of mumps-specific memory B lymphocytes is very low [11,12]. This could be due to poor antigenicity and low abundance of viral proteins during infection or possibly due to an inadequate T cell response.
Has the Virus Changed?
It is logical to suspect antigen drift as a possible explanation for breakthrough mumps infections among previously vaccinated populations. Although there are 12 recognized genotypes of mumps, there is only one serotype [13], meaning that antibody generated in response to infection with one strain of the virus can recognize the most genetically divergent strains. Interestingly, however, some reports indicate that there is often 2-to-16-fold variation in the amount of sera required from any given individual to neutralize genetically diverse mumps strains in vitro [14,15]. The reasons for this are not clear, but a possible cause is subtle variation in the neutralizing epitopes. Considering these observations, it has been postulated that an individual with very low levels of neutralizing antibody may become susceptible to some wild-type strains of the virus as his or her neutralizing antibody titer wanes.
There is evidence that mumps antibody may be boosted in vaccinated individuals by asymptomatic wild-type infection [16]. As endemic mumps virtually disappeared in the US, a consequent lack of natural boosting may have contributed to a reduction in population immunity to a level that is capable of sustaining transmission in some settings. Notably, recent outbreaks in the US have generally occurred in circumstances that promote a high frequency and intensity of contact, such as college dormitories, boarding schools, and youth summer camps, and spread of the virus beyond these settings into surrounding communities has been limited [17].
How Protective Is Mumps Vaccine?
The effectiveness of two doses of MMR vaccine is different for each virus component [2]. In contrast to the measles and rubella vaccines, which are ≥95% effective, reports of mumps vaccine effectiveness vary and range from 79%–95%, with a median of 88% [18]. Although it is imperfect, the protection afforded by mumps vaccination is effective, valuable, and important. As mentioned, high vaccination coverage has nearly eliminated endemic disease in the US and has limited spread of the virus to settings of high-intensity exposure. Furthermore, as compared to the prevaccine era, there has been a reduction in the frequency of complications among vaccinated individuals, which indicates there are important measures of protection that should not be overlooked [17]. Finally, there is no evidence of immune escape, indicating that vaccination should induce antibody that is capable of neutralizing wild-type virus.
Because of the lack of a well-defined correlate of immunity, it is not currently possible to predict with confidence whether or not someone who has been vaccinated is susceptible or protected. If a vaccinated individual does not have detectable mumps antibody, they may likely be susceptible, but this is not a forgone conclusion. The amount and specificity of antibody or other components of immunity that might be required for protection are simply not known.
Limited data are available regarding the effectiveness of a third dose of mumps vaccine [10]. During recent outbreaks when a third dose was given as a control measure, there was a reduction in disease incidence [19,20]. However, it is not clear from these reports if the outcome was a direct result of third-dose vaccination or if the reduction was simply the natural decline in disease incidence due to the late timing of the intervention in the course of the outbreak. In addition, limited antibody boosting was observed following third-dose vaccination, except in individuals who had extremely low (or no) mumps antibody [10].
Do We Need a New Mumps Vaccine and How Can We Make a Better One?
High expectations exist for the effectiveness of modern vaccines, in part due to the tremendous historic success of vaccination against viruses such as smallpox, polio, measles, rubella, and also mumps. It is important to remember, however, that not all pathogens are equivalent. There are significant fundamental differences in the ways they are transmitted, the pathologies they cause, and their interactions with the host immune system. Some of these differences may be reflected in the effectiveness of the respective vaccines and the longevity of the immune response to each.
It is reported that wild-type mumps (re)infections can occur more than once in the same individual [21]. Based on this observation—that not even wild-type mumps infection necessarily confers lifelong immunity—an important question is, what level of protection can be reasonably expected of any mumps vaccine? A more effective mumps vaccine that provides lifelong immunity is certainly desirable [22], but before scientifically grounded improvements can be made, it will be essential to better understand which parameters of immunity are required for protection and why the immune response to mumps is characteristically weak. Good animal models that accurately and consistently mimic the pathology and immune response to mumps virus infection in humans are lacking, although rhesus macaques tend to mirror the response the best and may be useful for future studies [23].
Zdroje
1. Dayan GH, Quinlisk MP, Parker AA, Barskey AE, Harris ML, Schwartz JM, et al. Recent resurgence of mumps in the United States. N Engl J Med. 2008;358(15):1580–9. doi: 10.1056/NEJMoa0706589 18403766
2. Plotkin SA, Orenstein WA, Offit PA. Vaccines. 5th ed. Philadelphia, Pa.: Saunders; 2008. xvii, 1725 p.
3. Katz SL, Hinman AR. Summary and conclusions: measles elimination meeting, 16–17 March 2000. J Infect Dis. 2004;189 Suppl 1:S43–7. 15106088
4. Centers for Disease C, Prevention. Elimination of rubella and congenital rubella syndrome—United States, 1969–2004. MMWR Morb Mortal Wkly Rep. 2005;54(11):279–82. 15788995
5. Anderson LJ, Seward JF. Mumps epidemiology and immunity: the anatomy of a modern epidemic. Pediatr Infect Dis J. 2008;27(10 Suppl):S75–9. doi: 10.1097/INF.0b013e3181684d8d 18820583
6. Rubin S, Eckhaus M, Rennick LJ, Bamford CG, Duprex WP. Molecular biology, pathogenesis and pathology of mumps virus. The Journal of pathology. 2015;235(2):242–52. doi: 10.1002/path.4445 25229387
7. Dittrich S, Hahne S, van Lier A, Kohl R, Boot H, Koopmans M, et al. Assessment of serological evidence for mumps virus infection in vaccinated children. Vaccine. 2011;29(49):9271–5. doi: 10.1016/j.vaccine.2011.09.072 21983156
8. Cortese MM, Barskey AE, Tegtmeier GE, Zhang C, Ngo L, Kyaw MH, et al. Mumps antibody levels among students before a mumps outbreak: in search of a correlate of immunity. J Infect Dis. 2011;204(9):1413–22. doi: 10.1093/infdis/jir526 21933874
9. Vandermeulen C, Leroux-Roels G, Hoppenbrouwers K. Mumps outbreaks in highly vaccinated populations: What makes good even better? Hum Vaccin. 2009;5(7):494–6. 19279405
10. Latner DR, McGrew M, Williams NJ, Sowers SB, Bellini WJ, Hickman CJ. Estimates of mumps seroprevalence may be influenced by antibody specificity and serologic method. Clin Vaccine Immunol. 2014;21(3):286–97. doi: 10.1128/CVI.00621-13 24371258
11. Latner DR, McGrew M, Williams N, Lowe L, Werman R, Warnock E, et al. Enzyme-linked immunospot assay detection of mumps-specific antibody-secreting B cells as an alternative method of laboratory diagnosis. Clin Vaccine Immunol. 2011;18(1):35–42. doi: 10.1128/CVI.00284-10 21047998
12. Vandermeulen C, Verhoye L, Vaidya S, Clement F, Brown KE, Hoppenbrouwers K, et al. Detection of mumps virus-specific memory B cells by transfer of peripheral blood mononuclear cells into immune-deficient mice. Immunology. 2010;131(1):33–9. doi: 10.1111/j.1365-2567.2010.03263.x 20586811
13. Mumps virus nomenclature update: 2012. Wkly Epidemiol Rec. 2012;87(22):217–24. 24340404
14. Rubin SA, Link MA, Sauder CJ, Zhang C, Ngo L, Rima BK, et al. Recent mumps outbreaks in vaccinated populations: no evidence of immune escape. J Virol. 2012;86(1):615–20. doi: 10.1128/JVI.06125-11 22072778
15. Rubin S, Mauldin J, Chumakov K, Vanderzanden J, Iskow R, Carbone K. Serological and phylogenetic evidence of monotypic immune responses to different mumps virus strains. Vaccine. 2006;24(14):2662–8. 16309801
16. Weibel RE, Buynak EB, McLean AA, Roehm RR, Hilleman MR. Persistence of antibody in human subjects for 7 to 10 years following administration of combined live attenuated measles, mumps, and rubella virus vaccines. Proc Soc Exp Biol Med. 1980;165(2):260–3. 7443713
17. Barskey AE, Schulte C, Rosen JB, Handschur EF, Rausch-Phung E, Doll MK, et al. Mumps outbreak in Orthodox Jewish communities in the United States. N Engl J Med. 2012;367(18):1704–13. doi: 10.1056/NEJMoa1202865 23113481
18. McClean HQH C.J.; Seward J.F. The Immunological Basis for Immunization Series, Module 16: Mumps. Geneva: World Health Organization; 2010. 44 p.
19. Nelson GE, Aguon A, Valencia E, Oliva R, Guerrero ML, Reyes R, et al. Epidemiology of a mumps outbreak in a highly vaccinated island population and use of a third dose of measles-mumps-rubella vaccine for outbreak control—Guam 2009 to 2010. Pediatr Infect Dis J. 2013;32(4):374–80. doi: 10.1097/INF.0b013e318279f593 23099425
20. Fiebelkorn AP, Lawler J, Curns AT, Brandeburg C, Wallace GS. Mumps postexposure prophylaxis with a third dose of measles-mumps-rubella vaccine, Orange County, New York, USA. Emerg Infect Dis. 2013;19(9):1411–7. doi: 10.3201/eid1909.130299 23965729
21. Yoshida N, Fujino M, Miyata A, Nagai T, Kamada M, Sakiyama H, et al. Mumps virus reinfection is not a rare event confirmed by reverse transcription loop-mediated isothermal amplification. J Med Virol. 2008;80(3):517–23. doi: 10.1002/jmv.21106 18205215
22. Plotkin SA. Commentary: Mumps vaccines: do we need a new one? Pediatr Infect Dis J. 2013;32(4):381–2. doi: 10.1097/INF.0b013e3182809dda 23552675
23. Xu P, Huang Z, Gao X, Michel FJ, Hirsch G, Hogan RJ, et al. Infection of mice, ferrets, and rhesus macaques with a clinical mumps virus isolate. J Virol. 2013;87(14):8158–68. doi: 10.1128/JVI.01028-13 23678169
Štítky
Hygiena a epidemiologie Infekční lékařství LaboratořČlánek vyšel v časopise
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